CN112556985B - Riparian zone lateral undercurrent exchange simulation device with adjustable length and test method - Google Patents
Riparian zone lateral undercurrent exchange simulation device with adjustable length and test method Download PDFInfo
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Abstract
The invention relates to a riparian zone lateral undercurrent exchange simulation device with adjustable length and a test method, wherein the device comprises: combining organic glass tanks: the device consists of an organic glass trough part R arranged at the right end for simulating a river channel, an organic glass trough part G arranged at the left end for simulating underground water and organic glass trough parts M with adjustable quantity, wherein a quartz sand layer is laid in a space between a left permeable sand baffle and a right permeable sand baffle; the water level control system: comprises a water supply component and a water abandoning component; conductivity monitoring system: comprises a conductivity data acquisition instrument and conductivity sensors respectively arranged at different heights and horizontal positions in a quartz sand layer. Compared with the prior art, the length of the simulation device can be adjusted according to different water level change requirements, the transverse-vertical undercurrent exchange process of the riparian zone can be accurately simulated based on the dynamic distribution of the conductivity, parameters such as the lateral undercurrent exchange range, the flux and the detention time are obtained, the operation is simple, and the disassembly and the installation are convenient.
Description
Technical Field
The invention relates to the field of hydraulic engineering tests, in particular to a riparian zone lateral undercurrent exchange simulation device with adjustable length and a test method.
Background
The river undercurrent zone is a sediment layer with water saturation in a riverbed and riverbank zones at two sides, and is an important transition area for dynamic interaction of surface water and underground water. The process that river water enters the underflow zone and is returned to the river channel after being retained for a period of time is the underflow exchange process, the method realizes the substance migration and energy transmission in the surface water-underground water transition zone, and has important significance in the aspects of substance circulation in the flow field, pollution reduction, ecological health maintenance and the like.
Early studies of the process of submerged exchange have focused primarily on vertical and longitudinal submerged exchange processes within the riverbed. In recent years, some researchers have conducted research on the exchange process of the river bank side-to-side underflow by means of on-site monitoring. However, under natural conditions, the influence factors of the undercurrent exchange are complicated, the influence degree of a single factor on the undercurrent exchange process is difficult to identify and describe, an indoor model test can control a single variable, and the influence of factors such as river channel water level change or underground water conditions on the river bank side undercurrent exchange process can be quantitatively researched.
The lateral undercurrent exchange depth under different water level change conditions is often different greatly, however, the indoor model size of the current research undercurrent exchange is usually fixed, so the test device is usually suitable for specific water level change conditions, in order to research the influence of different water level change conditions on the lateral undercurrent exchange of a riverbank zone, the development of a riverbank zone lateral undercurrent exchange simulation device with adjustable length for indoor tests is urgently needed, the comparison and analysis of a plurality of water level change conditions are realized, meanwhile, the test device is required to be reused, and the test cost is saved.
Disclosure of Invention
The invention aims to overcome the defects of the prior art and provide a simulation device and a test method for adjusting the length of the lateral undercurrent exchange of the riparian zone.
The purpose of the invention can be realized by the following technical scheme:
an adjustable length riparian zone lateral undercurrent exchange simulation apparatus, the apparatus comprising:
combining organic glass tanks: the device consists of an organic glass groove part R arranged at the right end for simulating a river channel, an organic glass groove part G arranged at the left end for simulating groundwater and organic glass groove parts M which are arranged between the organic glass groove part R and the organic glass groove part G and have adjustable quantity, wherein water-permeable sand baffles are arranged in the organic glass groove part R and the organic glass groove part G, and a quartz sand layer for simulating river bank zone sediments is laid in a space between the left water-permeable sand baffle and the right water-permeable sand baffle;
the water level control system: the device comprises a water supply assembly and a water abandoning assembly which are respectively connected with water tank water inlets and water outlets on an organic glass tank part G and an organic glass tank part R;
conductivity monitoring system: the device comprises a conductivity data acquisition instrument and a plurality of conductivity sensors which are respectively arranged at different heights and horizontal positions in a quartz sand layer and are respectively connected with the conductivity data acquisition instrument through leads, and are used for acquiring conductivity data in real time.
The organic glass groove component R is internally divided into a river channel water tank and a right bank sand groove by a permeable sand baffle vertically arranged through a clamping groove, the organic glass groove component G is internally divided into an underground water tank and a left bank sand groove by a permeable sand baffle vertically arranged through a clamping groove, and the right bank sand groove, the organic glass groove component M internal space and the left bank sand groove are communicated together to form the bank sand groove.
The back panel of the river channel water tank of the organic glass tank component R is provided with a river channel water tank water inlet, the front panel is provided with a plurality of groups of river channel water tank water outlets arranged at different heights, the back panel of the underground water tank of the organic glass tank component G is provided with an underground water tank water inlet, the front panel is provided with a plurality of underground water tank water outlets arranged at different heights, the river channel water tank water inlet is higher than the river channel water tank water outlet, and the underground water tank water inlet is higher than the underground water tank water outlet.
The permeable sand baffle is a porous organic glass plate, and nylon gauze is wrapped outside the permeable sand baffle to prevent test sand from being brought out by water.
The organic glass groove component M and the organic glass groove component R, the organic glass groove component M and the organic glass groove component G and the adjacent organic glass groove component M are all connected and molded through anchoring bolts in an anchoring mode, and a water-stopping rubber pad is arranged at the connecting position to guarantee the sealing performance.
The water supply assembly comprises an underground water tank water supply tank connected with an underground water tank water inlet through an underground water tank water inlet hose and a river channel water tank water supply tank connected with a river channel water tank water inlet through a river channel water tank water inlet hose, the underground water tank water inlet hose is provided with an underground water tank peristaltic pump, and the river channel water tank water inlet hose is provided with a river channel water tank peristaltic pump for controlling the water inlet flow of the water tank.
Abandon the water subassembly and abandon the water tank including the groundwater basin that is connected through groundwater basin play water hose and groundwater basin delivery port and abandon the water tank through the river course basin that river course basin play water hose and river course basin delivery port are connected, be equipped with the hose gasket respectively at the junction of groundwater basin play water hose and groundwater basin delivery port and the junction of river course basin play water hose and river course basin delivery port to be equipped with the stagnant water clamp respectively on river course basin play water hose and groundwater basin play water hose.
A layer of butyl water-stopping adhesive tape is laid at the bottom in the riparian zone sand groove and used for reducing the influence of the pores between sandy soil particles and the wall surface at the bottom of the organic glass on lateral underflow exchange.
The bottoms of the organic glass groove part R, the organic glass groove part G and the organic glass groove part M are provided with combined organic glass groove supporting bases.
A test method of a riparian zone lateral undercurrent exchange simulation device with adjustable length comprises the following steps:
1) determining the length of the combined organic glass groove:
setting the water level change process of underground water tanks and river water tanks on two sides in the combined organic glass tank according to the test purpose, measuring the horizontal permeability coefficient and porosity of a quartz sand layer (24), and estimating the undercurrent exchange depth according to Darcy's law, thereby determining the number of organic glass tank components M (29) and the length of the combined organic glass tank;
2) arranging sand filling and conductivity sensors:
quartz sand is laid between two permeable sand baffles (7) in the combined organic glass tank by adopting a layered vibrating compaction method, a plurality of conductivity sensors (22) are arranged at different heights and horizontal positions in a quartz sand layer (24) and are connected with a conductivity data acquisition instrument (23) through wires;
3) controlling the water level:
31) separately opening groundwater channels h0Height and river channel water channel H0Height of water stop clip of water outlet hose, and h0>H0Continuously supplying water by a peristaltic pump to keep the water level in the underground water tank unchanged and simulate the state of stable seepage of underground water to a river channel;
32) opening the conductivity data acquisition instrument (23), acquiring the initial value of the conductivity of the pore water of the quartz sand layer (24), putting conductive salt into the riverway water tank water supply tank (13) to a set concentration, and closing the initial water level H of the riverway water tank0The hose water stop clamp corresponding to the water outlet puts the conductive salt into the riverway water tank to the set concentration which is the same as the concentration of the conductive salt in the riverway water tank water supply tank, and simultaneously opens the peristaltic pump to control the concentration of the conductive salt to be q1Continuously supplying conductive salt solution with set concentration to the river channel water tank from a river channel water tank water supply tank (13) at a flow rate, and continuously lifting the water level in the river channel water tank;
33) when the water level of the river channel water tank reaches the target water level H1When the peristaltic pump is set to work reversely, the pump works with q2The flow draws water from the channel basin, and q2<q1When the water level of the channel water tank returns to the initial water level H0When the water level is high, the peristaltic pump is turned off, and the initial water level H of the riverway water tank is turned on0The hose water stop clamp corresponds to the water outlet;
4) conductivity monitoring and data processing:
41) and (3) conductivity monitoring:
continuously monitoring the conductivity values of the conductivity sensors (22) in the quartz sand layer (24) in the water level lifting process of the river channel water tank, and closing the conductivity data acquisition instrument (23) when the conductivity values of monitoring points in the quartz sand layer (24) tend to be stable, and ending the test;
42) data processing:
the conductivity value acquired by the conductivity sensor (22) is converted into a conductive salt concentration value, interpolation calculation is carried out on the conductive salt concentration value at the conductivity sensor (22) to obtain a conductive salt concentration field in the horizontal-vertical direction in the quartz sand layer (24), the range, the detention time and the flux of lateral undercurrent exchange in the water level lifting process of the river channel water tank are determined according to the dynamic change of the conductive salt concentration field, and the steps 3) and 4 are repeated to obtain the influence rule of different water level changes on the lateral undercurrent exchange of the river bank zone.
Compared with the prior art, the invention has the following advantages:
firstly, the length is adjustable: the length of the simulation device can be adjusted according to different water level change requirements, and compared with the existing model with a fixed size, the simulation device is more suitable for researching the lateral undercurrent exchange process of the riverbank zone under the change of river channel hydrological conditions.
Secondly, the operation is simple: the invention controls and simulates the river channel and the groundwater level through the peristaltic pump and the constant head drain hole, and has simple operation and short test time.
Thirdly, the measurement is comprehensive and accurate: the invention obtains the conductivity time sequence data of different positions through the conductivity sensors arranged in the quartz sand layer, thereby analyzing the transverse-vertical undercurrent exchange process and obtaining the lateral undercurrent exchange range, flux and residence time.
Fourthly, the disassembly and the installation are convenient: each part of the combined organic glass groove is convenient to disassemble and install, long in service life and easy to maintain.
Drawings
FIG. 1 is a schematic structural diagram of the present invention.
Fig. 2 is a schematic view of the length adjustment of the combined organic glass channel of the present invention.
FIG. 3 is a front view of a composite organic glass cell of the present invention.
FIG. 4 is a top view of a composite organic glass cell of the present invention.
Fig. 5 is a side view of a river channel trough of the present invention.
FIG. 6 is a side view of a groundwater table of the invention.
The notation in the figure is:
1. a slot, 2, a river channel water inlet, 3, a river channel water outlet, 4, an underground water channel water inlet, 5, an underground water channel water outlet, 6, an anchor bolt, 7, a permeable sand baffle, 8, a water stop rubber pad, 9, a river channel water channel, 10, a combined organic glass channel support base, 11, a river channel water channel peristaltic pump, 12, a river channel water inlet hose, 13, a river channel water supply tank, 14, a river channel water outlet hose, 15, a river channel water abandon tank, 16, a water channel, 17, an underground water channel peristaltic pump, 18, an underground water channel water inlet hose, 19, an underground water channel water supply tank, 20, an underground water channel water outlet hose, 21, an underground water abandon tank, 22, a conductivity sensor, 23, a conductivity data collector, 24, a quartz sand layer, 25, a butyl water stop tape, 26, a hose pad, 27, a clamp, 28, an underground water channel water tank water inlet, a channel water inlet hose, a hose pad, a channel water outlet, a channel water outlet, a channel outlet, a channel outlet, Organic glass tank members G, 29, organic glass tank members M, 30, and organic glass tank member R.
Detailed Description
The invention is further explained below with reference to the drawings and the embodiments, but the scope of protection of the invention is not limited by the embodiments.
Examples
As shown in fig. 1, the present invention provides a riparian zone lateral undercurrent exchange simulation apparatus with adjustable length, which comprises a combined organic glass tank, a water level control system and a conductivity monitoring system.
As shown in fig. 2, the combined organic glass tank is made of organic glass plates with a thickness of 2cm, and includes 1 organic glass tank part G28, 1 organic glass tank part R30 and a plurality of organic glass tank parts M29, wherein the organic glass tank part G28 and the organic glass tank part R30 are located at the left and right ends and are respectively used for simulating underground water and river channels, the organic glass tank part M29 is located in the middle and is used for simulating river bank zones, and the length of the simulation device can be adjusted by increasing or decreasing the number of the organic glass tank parts M29.
As shown in fig. 1 and fig. 3, each component of the combined organic glass trough is anchored by an anchoring bolt 6, a water-stop rubber pad 8 is arranged at the joint of each component to ensure the tightness, and the combined organic glass trough is 130cm long and 80cm high in the case of adopting 1 organic glass trough component M29.
As shown in fig. 1 and 4, the organic glass trough part G28 and the organic glass trough part R30 are both internally provided with a clamping groove 1 for fixing two vertically placed permeable sand-blocking plates 7, which are porous organic glass plates, and are externally wrapped with 300-mesh nylon gauze to prevent the test sand from being carried out by water; the combined organic glass tank is divided into three areas by the two water permeable sand baffles 7, namely an underground water tank, a riparian zone sand tank and a riverway water tank, wherein the riverway water tank 9 is 20cm long and 36cm wide, and the underground water tank 16 is 15cm long and 20cm wide.
As shown in figure 1, a quartz sand layer 24 with the thickness of 70cm is paved between two water-permeable sand baffles 7 in the combined organic glass groove to be used as river bank sediment, and a butyl water-stop adhesive tape 25 with the thickness of 3mm is paved at the bottom of the sand layer to reduce the influence of the pores between sandy soil particles and the bottom wall surface of organic glass on lateral undercurrent exchange.
The water level control system consists of a water supply tank, a peristaltic pump, a water inlet hose, a water discharge hose, a waste water tank and the like.
As shown in fig. 1 and 5, the height of the water inlet 2 of the river channel water tank is 70cm away from the bottom in the tank, and the water inlet is connected with a water supply tank 13 of the river channel water tank through a water inlet hose 12 of the river channel water tank and a peristaltic pump 11 of the river channel water tank; the water outlets 3 of the river channel water tank are provided with 5 rows which are respectively arranged at the height positions 20cm, 30cm, 40cm, 50cm and 60cm away from the bottom in the tank, each row is provided with 2 water outlets, the water outlets are connected with a water discard tank 15 of the river channel water tank through water outlet hoses 14 of the river channel water tank, the water outlet hoses are provided with water stop clamps 27, and hose pads 26 are arranged at the water outlets and can fix the hoses and prevent water leakage; the water inlet and the water outlet of the river channel water tank are round holes, and the diameters of the round holes are both 2 cm.
As shown in fig. 1 and fig. 6, the height of the inlet 4 of the groundwater tank is 70cm away from the bottom in the tank, and the groundwater tank inlet hose 18 and the groundwater tank peristaltic pump 17 are connected with a groundwater tank water supply tank 19; 5 rows of the water outlets 5 of the underground water tank are respectively arranged at the height positions 20cm, 30cm, 40cm, 50cm and 60cm away from the bottom in the tank, 1 water outlet is arranged in each row, the underground water tank is connected with a waste water tank 21 of the underground water tank through a water outlet hose 20 of the underground water tank, the water outlet hose is provided with a water stop clamp 27, and a hose gasket 26 is arranged at the water outlet to fix the hose and prevent water leakage; the water inlet and the water outlet of the underground water tank are round holes with the diameter of 2 cm.
As shown in fig. 1, the riverway water tank peristaltic pump 11 and the underground water tank peristaltic pump 17 are both alternating current intelligent peristaltic pumps, and can accurately regulate and control the water delivery flow and the water delivery direction; the maximum flow of the riverway water tank peristaltic pump is 6L/min, the minimum flow of the riverway water tank peristaltic pump is 0.25ml/min, the maximum flow of the underground water tank peristaltic pump is 1.6L/min, and the minimum flow of the underground water tank peristaltic pump is 0.1 ml/min.
As shown in fig. 1, the conductivity monitoring system is composed of a plurality of conductivity sensors 22 and 1 conductivity data collector 23, wherein the conductivity sensors 22 are buried at different heights and horizontal positions in a quartz sand layer 24, are connected with the conductivity data collector 23 through wires, and record conductivity values of monitoring points in the sand layer in the test process in real time.
In this example, the test method of the adjustable-length riparian zone lateral undercurrent exchange simulation device comprises the following steps:
step 1: determining the length of the combined organic glass groove;
setting the water level change process of water tanks on two sides in the combined organic glass tank according to the test purpose, measuring the horizontal permeability coefficient and porosity of the quartz sand layer, and estimating the undercurrent exchange depth according to Darcy's law, thereby determining the number of the organic glass tank components M and the length of the combined organic glass;
step 2: arranging sand filling and conductivity sensors;
laying sandy soil between two permeable sand baffles in the combined organic glass tank in a layered manner, controlling each layer of sandy soil according to the thickness of 5cm, compacting by adopting vibration, and arranging conductivity sensors in the sand layer at equal intervals of 10cm in the horizontal direction and the vertical direction;
and step 3: controlling the water level;
respectively opening 16 water levels h of the underground water tank0And initial water level H of river channel water tank 90The hose water stop clamp 27 corresponding to the water outlet continuously supplies water through the underground water tank peristaltic pump 17 to keep the water level of the underground water tank unchanged and simulate the state of stable seepage of underground water to a river channel; opening the conductivity data acquisition instrument 23 to obtain an initial value of the pore water conductivity of the sand layer 24; putting conductive salt into the riverway water tank water supply tank 13 to a set concentration; closing initial water level H of river channel water tank0The hose water stop clamp corresponding to the water outlet puts conductive salt into the riverway water tank to the set concentration and the concentration of the conductive salt in the riverway water tank water supply tank, and simultaneously opens the riverway water tank peristaltic pump 11 to use q1Flow from riverThe water channel water tank 13 continuously supplies water to the river channel water tank 9, and the water level of the river channel water tank continuously rises; when the water level of the river channel water tank reaches the target water level H1When the river channel water tank peristaltic pump 11 is set to work reversely, and q is used for controlling the water tank peristaltic pump to work reversely2Flow rate q2<q1Pumping water from the channel water tank until the channel water tank level returns to the initial level H0Closing the riverway water tank peristaltic pump 11 and simultaneously opening the initial water level H of the riverway water tank0A hose water stop clip 27 corresponding to the water outlet;
and 4, step 4: conductivity monitoring and data processing
Continuously monitoring conductivity values of all sensors in the sand layer 24 in the water level lifting process of the riverway water channel; when the conductivity values of the monitoring points in the sand layer tend to be stable, the conductivity data acquisition instrument 23 is closed, and the test is finished; converting conductivity values collected by the conductivity sensor 22 into conductivity salt concentration values; conducting salt concentration values at the sensor are subjected to interpolation calculation to obtain conducting salt concentration fields in the horizontal-vertical direction in the sand layer; determining the range, residence time and flux of lateral undercurrent exchange in the water level lifting process of the river channel water tank according to the dynamic change of the conductive salt concentration field; and (5) repeating the test steps 3 and 4, and analyzing the influence rule of different water level changes on the lateral undercurrent exchange of the riparian zone.
The non-illustrated parts referred to in the present invention are the same as or implemented by the prior art.
The above are merely examples of the present invention and do not limit the scope of the invention. Equivalent structures or changes made by using the contents of the specification and the drawings of the invention or applied to other related technical fields are included in the scope of the invention.
Claims (9)
1. An adjustable length riparian zone lateral undercurrent exchange simulation device, characterized in that it comprises:
combining organic glass tanks: the organic glass groove component G (28) is composed of an organic glass groove component R (30) arranged at the right end and used for simulating a river channel, an organic glass groove component G (28) arranged at the left end and used for simulating groundwater, and an organic glass groove component M (29) arranged between the organic glass groove component R (30) and the organic glass groove component G (28) and adjustable in quantity, a permeable sand baffle (7) is arranged in the organic glass groove component R (30) and the organic glass groove component G (28), a quartz sand layer (24) used for simulating river bank sediment is laid in the space between the left permeable sand baffle and the right permeable sand baffle (7), the organic glass groove component R (30) is internally divided into the river channel and a right river bank sand channel through the permeable sand baffle (7) vertically arranged through a clamping groove (1), and the organic glass groove component G (28) is internally divided into the river channel and the right bank sand channel through the permeable sand baffle (7) vertically arranged through the clamping groove (1) ) The inner space is divided into a groundwater tank and a left bank belt sand groove, and the right bank belt sand groove, the inner space of the organic glass groove component M (29) and the left bank belt sand groove are communicated together to form the bank belt sand groove;
the water level control system: comprises a water supply component and a water discharge component which are respectively connected with the water tank water inlet and outlet on an organic glass tank part G (28) and an organic glass tank part R (30);
conductivity monitoring system: the device comprises a conductivity data acquisition instrument (23) and a plurality of conductivity sensors (22) which are respectively arranged at different heights and horizontal positions in a quartz sand layer (24) and are respectively connected with the conductivity data acquisition instrument (23) through leads, and are used for acquiring conductivity data in real time.
2. The riverbank area lateral undercurrent exchange simulation device with the adjustable length as claimed in claim 1, wherein a riverway water tank water inlet (2) is formed in a riverway water tank rear panel of the organic glass tank component R (30), a plurality of groups of riverway water tank water outlets (3) arranged at different heights are formed in a front panel, an underground water tank water inlet (4) is formed in an underground water tank rear panel of the organic glass tank component G (28), a plurality of underground water tank water outlets (5) arranged at different heights are formed in the front panel, the riverway water tank water inlet (2) is higher than the riverway water tank water outlets (3), and the underground water tank water inlet (4) is higher than the underground water tank water outlet (5).
3. The adjustable-length riparian zone lateral undercurrent exchange simulation device according to claim 1, wherein the water-permeable sand barrier (7) is a porous organic glass plate, and nylon gauze is wrapped outside the porous organic glass plate to prevent the test sand from being carried out by water.
4. The adjustable-length riparian zone lateral undercurrent exchange simulation device according to claim 1, wherein the organic glass trough member M (29) and the organic glass trough member R (30), the organic glass trough member M (29) and the organic glass trough member G (28) and the adjacent organic glass trough member M (29) are connected in a anchoring manner through anchoring bolts (6), and a sealing rubber gasket (8) is arranged at the connection position to ensure the sealing property.
5. The riverside undercurrent exchange simulation device of the riverbank area with the adjustable length as claimed in claim 2, wherein the water supply assembly comprises an underground water tank water supply tank (19) connected with the underground water tank water inlet (4) through an underground water tank water inlet hose (18) and a riverway tank water supply tank (13) connected with the riverway tank water inlet (2) through a riverway tank water inlet hose (12), the underground water tank water inlet hose (18) is provided with an underground water tank peristaltic pump (17), and the riverway tank water inlet hose (12) is provided with a riverway tank peristaltic pump (11) for controlling the water inlet flow of the water tank.
6. The riverbank side undercurrent exchange simulation device with the adjustable length as claimed in claim 2, wherein the water abandoning assembly comprises an underground water tank water abandoning tank (21) connected with the underground water tank water outlet (5) through an underground water tank water outlet hose (20) and a riverway tank water abandoning tank (15) connected with the riverway tank water outlet (3) through a riverway tank water outlet hose (14), hose pads (26) are respectively arranged at the connection part of the underground water tank water outlet hose (20) and the underground water tank water outlet (5) and the connection part of the riverway tank water outlet hose (14) and the riverway tank water outlet (3), and water stop clamps (27) are respectively arranged on the riverway tank water outlet hose (14) and the underground water tank water outlet hose (20).
7. The adjustable-length simulation device for lateral undercurrent exchange of riverbank belts as claimed in claim 1, wherein a layer of butyl water-stop adhesive tape (25) is laid at the bottom of the sand groove of the riverbank belt to reduce the influence of the pores between the sandy soil particles and the bottom wall surface of the organic glass on the lateral undercurrent exchange.
8. A simulation device of riverbank zone side undercurrent exchange with adjustable length according to claim 1, characterized in that the bottom of the organic glass tank member R (30), the organic glass tank member G (28) and the organic glass tank member M (29) are provided with a combined organic glass tank supporting base (10).
9. A test method using the adjustable-length riparian zone lateral undercurrent exchange simulation apparatus of claim 1, comprising the steps of:
1) determining the length of the combined organic glass groove:
setting the water level change process of underground water tanks and river water tanks on two sides in the combined organic glass tank according to the test purpose, measuring the horizontal permeability coefficient and porosity of a quartz sand layer (24), and estimating the undercurrent exchange depth according to Darcy's law, thereby determining the number of organic glass tank components M (29) and the length of the combined organic glass tank;
2) arranging sand filling and conductivity sensors:
quartz sand is laid between two permeable sand baffles (7) in the combined organic glass tank by adopting a layered vibrating compaction method, a plurality of conductivity sensors (22) are arranged at different heights and horizontal positions in a quartz sand layer (24) and are connected with a conductivity data acquisition instrument (23) through wires;
3) controlling the water level:
31) separately opening groundwater channels h0Height and river channel water channel H0Height of water stop clip of water outlet hose, and h0>H0Continuously supplying water by a peristaltic pump to keep the water level in the underground water tank unchanged and simulate the state of stable seepage of underground water to a river channel;
32) opening the conductivity data acquisition instrument (23), acquiring the initial value of the conductivity of the pore water of the quartz sand layer (24), putting conductive salt into the riverway water tank water supply tank (13) to a set concentration, and closing the initial water level H of the riverway water tank0The hose water stop clamp corresponding to the water outlet puts the conductive salt into the riverway water tank to the set concentration which is the same as the concentration of the conductive salt in the riverway water tank water supply tank, and simultaneously opens the peristaltic pump to control the concentration of the conductive salt to be q1Continuously supplying conductive salt solution with set concentration to the river channel water tank from a river channel water tank water supply tank (13) at a flow rate, and continuously lifting the water level in the river channel water tank;
33) when the water level of the river channel water tank reaches the target water level H1When the peristaltic pump is set to work reversely, the pump works with q2The flow draws water from the channel basin, and q2<q1When the water level of the channel water tank returns to the initial water level H0When the water level is high, the peristaltic pump is turned off, and the initial water level H of the riverway water tank is turned on0The hose water stop clamp corresponds to the water outlet;
4) conductivity monitoring and data processing:
41) and (3) conductivity monitoring:
continuously monitoring the conductivity values of the conductivity sensors (22) in the quartz sand layer (24) in the water level lifting process of the river channel water tank, and closing the conductivity data acquisition instrument (23) when the conductivity values of monitoring points in the quartz sand layer (24) tend to be stable, and ending the test;
42) data processing:
the conductivity value acquired by the conductivity sensor (22) is converted into a conductive salt concentration value, interpolation calculation is carried out on the conductive salt concentration value at the conductivity sensor (22) to obtain a conductive salt concentration field in the horizontal-vertical direction in the quartz sand layer (24), the range, the detention time and the flux of lateral undercurrent exchange in the water level lifting process of the river channel water tank are determined according to the dynamic change of the conductive salt concentration field, and the steps 3) and 4 are repeated to obtain the influence rule of different water level changes on the lateral undercurrent exchange of the river bank zone.
Priority Applications (1)
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